Hostname: page-component-599cfd5f84-9hh9z Total loading time: 0 Render date: 2025-01-07T05:42:05.398Z Has data issue: false hasContentIssue false
  • English
  • Français

Bomb Carbon as a Tracer of Dietary Carbon Sources in Omnivorous Mammals

Published online by Cambridge University Press:  18 July 2016

Nancy Beavan-Athfield  and
Rodger J Sparks
Nancy Beavan-Athfield
Affiliation:
Rafter Radiocarbon Laboratory, Institute of Geological and Nuclear Sciences, PO Box 31-312, Lower Hutt, New Zealand. Email: [email protected]
Rodger J Sparks
Affiliation:
Rafter Radiocarbon Laboratory, Institute of Geological and Nuclear Sciences, PO Box 31-312, Lower Hutt, New Zealand. Email: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Core share and HTML view are not available for this content. However, as you have access to this content, a full PDF is available via the ‘Save PDF’ action button.

We have isolated amino acid groups from modern bone hydrolysates and compared their relative Δ14C value to assess the carbon contribution of diet to the overall radiocarbon signal in bone. We find that both essential and non-essential amino acids may produce widely varying 14C, relative to other amino acid groups in the hydrolysate and to the original whole bone protein. We hypothesize that the 14C variations in non-essential amino acids may be due to metabolic effects that utilize essential amino acid carbon skeletons in the creation of non-essential amino acids.

Type
I. Our ‘Dry’ Environment: Above Sea Level
Information
Radiocarbon , Volume 43 , Issue 2B: Proceedings of the 17th International Radiocarbon Conference (Part 2 of 3), Conference Editors: Israel Carmi, Elisabetta Boaretto , 2001 , pp. 711 - 721
Copyright
Copyright © 2001 by the Arizona Board of Regents on behalf of the University of Arizona 

References

Ambrose, SH, Norr, L. 1993. Experimental evidence for the relationship of the carbon isotope ratios of whole diet and dietary protein to those of bone collagen and carbonate In: Mabert, JB, Grupe, G, editors. Prehistoric human bone - archaeology at the molecular level. Berlin: Springer-Verlag. p 138.Google Scholar
Beavan, NR, Sparks, RJ. 1998. Factors influencing 14C ages of the Pacific Rat Rattus exulans. Radiocarbon 40(2):601–13.Google Scholar
Bettelheim, FB, March, J. 1998. Introduction to general, organic & biochemistry. 5th edition. Sydney: Harcourt Brace. p 679.Google Scholar
Booth, AM, Minot, EO, Fordham, RA, Innes, JG. 1996. Kiore (Rattus exulans) predation on the eggs of the Little Shearwater (Puffinus assimilis baurakiensis). Notornis 43:147–53.Google Scholar
Broecker, WS, Walton, A. 1959. Radiocarbon from nuclear tests. Science 130:309–14.Google Scholar
Bunn, TJ, Craig, JL. 1989. Population cycles of Rattus exulans: population changes, diet, and food availability. New Zealand Journal of Zoology 16:409–18.Google Scholar
Craig, JL. 1986. The effects of kiore on other fauna. In: Wright, AE, Beever, RE, editors. The offshore islands of northern New Zealand. Wellington: New Zealand Department of Lands and Survey Information 16. p 419–25.Google Scholar
Fuller, SA. 1994. Biological indexing on Kapiti Island, a preliminary assessment, March-June 1994. Wellington: New Zealand Department of Conservation.Google Scholar
Garlick, PJ, McNurlan, MA, Patlak, CS. 1999. Adaption of protein metabolism in relation to limits to high dietary protein intake. European Journal of Clinical Nutrition. 53(Supplement 1):3443.Google Scholar
Gulliksen, S, Scott, M. 1995. Report of the TIRI workshop. Radiocarbon 37(2):820–1.Google Scholar
Hare, PE, Fogal, ML, Stafford, TW, Mitchell, AD, Hoering, TC. 1991. The isotopic composition of carbon and nitrogen in individual amino acids isolated from modern and fossil proteins. Journal of Archaeological Science 18:277–92.Google Scholar
Hubbard, MJ. 1995. Amino acid analysis. European Journal of Biochemistry 230:6879.CrossRefGoogle Scholar
Lehninger, AL. 1982 Principles of biochemistry. New York: Worth Publishers, p 545.Google Scholar
Macko, SA, Fogal, ML, Hare, PE, Hoering, TC. 1987. Isotopic fractionation of nitrogen and carbon in the synthesis of amino acids by microorganisms. Chemical Geology 65:7992.CrossRefGoogle Scholar
Manning, MR, Lowe, DC, Melhuish, WH, Sparks, RJ, Wallace, G, Brenninkmeijer, CAM, McGill, RC. 1990. The use of radiocarbon measurements in atmospheric studies. Radiocarbon 32(1):3758.Google Scholar
Nydal, R, Lovseth, K, Syrstad, O. 1971. Bomb 14C in the human population. Nature 232:418–21.Google Scholar
Obled, C, Arnal, M, Fauconneau, G. 1983. Whole-body threonine, leucine, tyrosine, lysine and histidine fluxes during post weaning development of the rat. Les Colloques de l'INRA 16:23–7.Google Scholar
Schoeninger, MJ, DeNiro, MJ. 1984. Nitrogen and carbon isotopic composition of bone collagen from marine and terrestrial animals. Geochimica et Cosmochemica Acta 48:625–39.Google Scholar
Stuiver, M, Polach, HA. 1977. Discussion: reporting of 14C data. Radiocarbon 19(2):355–63.Google Scholar
Tanaka, H, Nakatomi, Y, Takahashi, K, Ogura, M. 1991. Metabolism of lysine and tryptophan in growing rats at various dietary levels. Agricultural and Biological Chemistry 55:531–7.Google Scholar
Tieszen, LL, Boutton, TW, Tesdahl, KG, Slade, NA. 1983. Fractionation and turnover of stable carbon isotopes in animal tissues: implications for 13C analysis of diet. Oecologia (Berlin) 57:32–7.Google Scholar
Yudkin, M, Offord, R. 1973. Comprehensible biochemistry. Sydney: Longman Group Limited. p 360, 382.Google Scholar